JP2022182742A - Storage battery management system - Google Patents

Abstract

To provide a storage battery management system in which a storage battery has a communication function and can control various apparatuses.SOLUTION: A storage battery management system 1 of the present disclosure includes: a storage battery pack 10; and a power control apparatus 20 that the storage battery pack 10 is attached to and detached from and that performs power control, which is control of at least one of charging and discharging of the storage battery pack 10. The storage battery pack 10 includes: a first communication unit 12 that receives schedule information indicating a schedule for power control from an information terminal 30 or a server; a second communication unit 15 that communicates with the power control apparatus 20; and a first control unit 13 that transmits execution information for executing power control to the power control apparatus 20 using the second communication unit 15 based on the received schedule information.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to battery management systems.

2. Description of the Related Art Conventionally, there are household storage battery devices that are charged at night when electricity rates are low and supply power during daytime when electricity rates are high. In Patent Document 1, the prediction error of the generated power of a private power generator and the prediction error of the power consumption of a load in the past stored in a storage unit are evaluated, and the predicted value of the generated power and the predicted value of the power consumption of the next day are calculated. , respectively, and based on the difference power between the corrected predicted value of generated power and predicted value of consumed power, a method of operating a storage battery and a power control device for calculating the charging power amount of a storage battery charged at night are disclosed. It is

JP 2015-213389 A

However, the storage battery in the power control device disclosed in Patent Document 1 does not have a communication function, and the storage battery cannot control various devices.

Accordingly, the present disclosure provides a storage battery management system in which the storage battery has a communication function and the storage battery can control various devices.

A storage battery management system according to an aspect of the present disclosure includes a storage battery pack, and a power control device to which the storage battery pack is attached and detached and which performs power control, which is control of at least one of charging and discharging of the storage battery pack, wherein the storage battery The pack includes a first communication unit that receives schedule information indicating the power control schedule from an information terminal or a server, a second communication unit that communicates with the power control device, and based on the received schedule information, and a first control unit that transmits execution information for executing the power control to the power control device using the second communication unit.

In addition, these general or specific aspects may be realized by an apparatus, method, integrated circuit, computer program, or a recording medium such as a computer-readable CD-ROM. and any combination of recording media.

In the storage battery management system according to one aspect of the present disclosure, the storage battery has a communication function and can control various devices.

FIG. 1 is a block diagram of a storage battery management system according to an embodiment. FIG. 2 is a diagram showing an example of a battery pack used in the battery management system according to the embodiment. FIG. 3 is a block diagram when the storage battery pack of the storage battery management system in the embodiment controls the power control device. FIG. 4 is a block diagram when the power control device of the storage battery management system in the embodiment controls itself. FIG. 5 is a diagram showing the flow of electric power during charging in the storage battery management system according to the embodiment. FIG. 6 is a diagram showing the flow of electric power during discharging in the storage battery management system according to the embodiment. FIG. 7 is a diagram showing charge/discharge patterns of the storage battery management system in the embodiment. FIG. 8 is a flow chart showing the operation of setting the timer or capacity of the storage battery management system in the embodiment. FIG. 9 is a flowchart showing charge/discharge operation of the storage battery management system in the embodiment. FIG. 10 is a diagram showing the relationship of main components of the storage battery management system according to the embodiment.

(Embodiment)
First, an outline of the storage battery management system in the embodiment will be described. FIG. 1 is a block diagram of a storage battery management system 1 according to an embodiment.

The storage battery management system 1 includes a storage battery pack 10 , a power control device 20 and an information terminal 30 .

The storage battery pack 10 includes a storage battery unit 11, a first communication unit 12, a first control unit 13, a storage unit 14, a second communication unit 15, a discharging terminal 16, a communication terminal 17, and a charging terminal 18. Prepare. The power control device 20 also includes a second control unit 21 , a first switching unit 22 , a conversion unit 23 , a charging power source 24 , a second switching unit 25 , an input unit 26 , and an output unit 27 .

The storage battery unit 11 is a storage battery that charges electricity. The storage battery unit 11 is, for example, a lithium ion battery that is a secondary battery that charges and discharges by moving lithium ions between a positive electrode and a negative electrode. Lithium cobalt oxide, lithium manganate, lithium iron phosphate, or the like may be used for the positive electrode of the storage battery unit 11 . The storage battery unit 11 performs charging or discharging under the control of the second control unit 21 . The storage battery unit 11 receives electricity from the charging terminal 18 when charging. Moreover, the storage battery part 11 sends electricity to the discharge terminal 16, when discharging.

The first communication unit 12 is a communication circuit that performs wireless communication. The first communication unit 12 may be a communication circuit that can also perform wired communication. The first communication unit 12 performs wireless communication with the information terminal 30 and receives from the information terminal 30 schedule information indicating the schedule of power control performed by the second control unit 21 of the power control device 20 . The power control schedule is a schedule (schedule information) for charging or discharging performed by the storage battery unit 11 . Also, the first communication unit 12 may communicate with a server device that implements a cloud that stores schedule information and the like. Note that the first communication unit 12 communicates with the information terminal 30 that has received information from the server device by communicating with the server device that realizes the cloud, and acquires the information that the information terminal 30 has received from the server device. You may

The first control unit 13 is implemented by a circuit and a memory. The first control unit 13 transmits execution information for executing power control to the power control device 20 using the second communication unit 15 based on the schedule information received by the first communication unit 12 . The first control unit 13 also transmits a command based on the schedule information to the power control device 20 as execution information.

The storage unit 14 is implemented by a memory. The storage unit 14 stores schedule information received by the first communication unit 12 , control information for controlling the power control device 20 transmitted by the second communication unit 15 to the second control unit 21 , and the like. Information stored in the storage unit 14 may include time information.

The second communication unit 15 is a communication circuit that performs wired communication. The second communication unit 15 may be a communication circuit that can also perform wireless communication. The second communication unit 15 communicates with the power control device 20 . Specifically, the first control unit 13 uses the second communication unit 15 to transmit execution information for executing power control to the power control device 20 based on the received schedule information.

The discharge terminal 16 is a terminal for receiving electricity discharged by the storage battery section 11 . The discharge terminal 16 may be made of metal. The electricity received by the discharge terminal 16 from the storage battery section 11 is output from the output section 27 to an external load device or the like via the first switching section 22 .

The communication terminal 17 is a terminal for the second communication section 15 to perform wired communication with the second control section 21 . The communication terminal 17 may be made of metal. The communication terminal 17 may be a terminal through which the second communication section 15 wirelessly communicates with the second control section 21 . The communication terminal 17 may transmit schedule information, control information for controlling the power control device 20 , and the like to the second control unit 21 .

The charging terminal 18 is a terminal for supplying electricity to be charged by the storage battery section 11 . The charging terminal 18 may be made of metal. The charging terminal 18 receives the power from the system power source acquired by the input unit 26 via the second switching unit 25 and supplies the received power to the storage battery unit 11 .

The second control unit 21 is realized by a circuit and a memory. The second control unit 21 receives the schedule information and performs power control on the storage battery pack 10 based on the received schedule information.

For example, the second control unit 21 controls the second switching unit 25 to energize the charging terminal 18 and charge the storage battery unit 11 at the timing when the schedule information indicates charging. On the contrary, the second control unit 21 discharges the storage battery unit 11 at the timing when the schedule information indicates that the discharge is to be performed, and controls the first switching unit 22 to discharge the electricity received by the discharge terminal 16. Send to the output unit 27 .

The first switching unit 22 is a switching unit that switches paths for flowing the power that the input unit 26 acquires from the system power supply to the output unit 27 as it is. The power control device 20 controls the first switching unit 22 when the power acquired by the input unit 26 from the system power supply is not sent to the storage battery pack 10 but is sent directly from the output unit 27 to the load device. , the path from the input section 26 to the output section 27 is energized. Further, when the storage battery unit 11 of the storage battery pack 10 is discharged, the power control device 20 controls the first switching unit 22 to send the power discharged by the storage battery unit 11 to the output unit 27 via the conversion unit 23. .

The conversion unit 23 converts the DC power discharged by the storage battery unit 11 into AC power. The conversion unit 23 is realized by an inverter or the like.

The charging power supply 24 is a power supply that drives the power control device 20 and charges the power received by the input unit 26 from the system power supply.

The second switching unit 25 is a switching unit that switches the route for sending the power acquired by the input unit 26 to the storage battery unit 11 . When the power control device 20 sends power acquired by the input unit 26 from the system power supply to the storage battery pack 10 , the power control device 20 switches the second switching unit 25 to send power to the storage battery unit 11 via the charging terminal 18 .

The input unit 26 receives input of electric power from the system power supply. The input section 26 may be realized by metal terminals. The input unit 26 acquires power from the system power supply and sends it to the charging power supply 24 . Alternatively, the input unit 26 acquires power from the system power supply and sends the power to the output unit 27 via the first switching unit 22 .

The output unit 27 outputs electric power to a load device or the like. The output section 27 may be implemented by a metal terminal. The output unit 27 receives power discharged by the storage battery unit 11 via the conversion unit 23 and the first switching unit 22 , or receives power acquired by the input unit 26 via the first switching unit 22 .

The information terminal 30 is realized by a smart phone, a tablet terminal, a server terminal, or the like. The information terminal 30 transmits schedule information indicating the schedule of power control to the first communication unit 12 by wireless communication or the like. Further, when the information terminal 30 is a server terminal, the server terminal issues an instruction to the storage battery pack 10 in an emergency to update the schedule information indicating the timing to charge or discharge the storage battery pack 10 included in the charge/discharge information. Send to Pack 10.

Next, the storage battery pack 10 used in the storage battery management system 1 will be described. FIG. 2 is a diagram showing an example of the storage battery pack 10 used in the storage battery management system 1 according to the embodiment. The storage battery pack 10 includes a lithium ion battery and has a communication function such as Bluetooth (registered trademark). The appearance of the storage battery pack 10 is shown in FIG. 2(a). Also, as shown in FIG. 2(b), the output terminal is a USB port.

Next, a case where the storage battery pack 10 controls the power control device 20 will be described. FIG. 3 is a block diagram when the storage battery pack 10 of the storage battery management system 1 in the embodiment controls the power control device 20. As shown in FIG.

First, the information terminal 30 sets schedule information indicating a schedule for charging and discharging the storage battery unit 11 and transmits the set schedule information to the first communication unit 12 of the storage battery pack 10 .

Next, the first control unit 13 of the storage battery pack 10 uses the second communication unit 15 to transmit execution information for executing power control in the power control device 20 to the second control unit 21 . Here, the first control unit 13 generates execution information based on the schedule information received by the first communication unit 12 . By operating the power control device 20 , charging and discharging of the storage battery pack 10 are controlled in the storage battery management system 1 .

The execution information may be, for example, information that causes the second control unit 21 to turn on or off the first switching unit 22 and the second switching unit 25 based on schedule information.

When the storage battery pack 10 controls the power control device 20 , the first control unit 13 uses the second communication unit 15 to transmit only execution information to the second control unit 21 without transmitting schedule information. The second control unit 21 controls the first switching unit 22, the second switching unit 25, etc. based only on the execution information, not on the schedule information.

Next, a case where power control device 20 performs power control based on information transmitted from storage battery pack 10 will be described. FIG. 4 is a block diagram when power control device 20 of storage battery management system 1 in the embodiment controls itself.

First, the information terminal 30 sets schedule information indicating a schedule for charging and discharging the storage battery unit 11 and transmits the set schedule information to the first communication unit 12 of the storage battery pack 10 .

Next, the first control unit 13 of the storage battery pack 10 uses the second communication unit 15 to transmit the schedule information received by the first communication unit 12 to the second control unit 21 .

Subsequently, the second control unit 21 generates execution information based on the received schedule information. As described above, the execution information may be, for example, information that causes the second control unit 21 to turn on or off the first switching unit 22 and the second switching unit 25 based on schedule information.

When the power control device 20 performs power control, the first control unit 13 uses the second communication unit 15 to transmit only schedule information to the second control unit 21 . The second control unit 21 generates execution information based on the schedule information, and controls the first switching unit 22, the second switching unit 25 and the like based on the execution information. At this time, the second control unit 21 obtains the date and time information from the first control unit 13 that transmits the information using the second communication unit 15 .

Next, the flow of electric power during charging of the storage battery management system 1 will be described. FIG. 5 is a diagram showing the flow of electric power during charging in the storage battery management system 1 according to the embodiment.

When the storage battery unit 11 is being charged, electric power passes from the input unit 26 through the charging power supply 24 , the second switching unit 25 , and reaches the second control unit 21 . After that, the electric power passes through the charging terminal 18 , reaches the first control section 13 , and reaches the storage battery section 11 .

At this time, part of the power may flow from the input section 26 through the first switching section 22 to the output section 27 (hereinafter referred to as pass-through output).

Further, when the information terminal 30 sets the schedule information, the information terminal 30 may receive input of the following information from the user in the input unit provided in the information terminal 30 . The input information received by the information terminal 30 includes, for example, charging start time, charging end time, charging capacity, and presence/absence of regular setting. If the information terminal 30 is a tablet terminal or a smart phone, the input unit may be a screen.

Next, the flow of electric power during discharging of the storage battery management system 1 will be described. FIG. 6 is a diagram showing the flow of electric power during discharging in the storage battery management system according to the embodiment.

When the storage battery unit 11 is discharging, electric power passes from the storage battery unit 11 through the discharge terminal 16 and reaches the second control unit 21 . The power then passes through the converter 23 , the first switching unit 22 , and reaches the output unit 27 .

Further, when the information terminal 30 sets the schedule information, the information terminal 30 may receive input of the following information from the user in the input unit provided in the information terminal 30 . Input information received by the information terminal 30 includes discharge start time, discharge end time, discharge capacity, and presence/absence of regular setting. If the information terminal 30 is a tablet terminal or a smart phone, the input unit may be a screen.

Next, examples of charge/discharge patterns of the storage battery management system 1 will be described. FIG. 7 is a diagram showing charge/discharge patterns of the storage battery management system 1 in the embodiment. For example, the storage battery management system 1 starts charging the storage battery unit 11 at 23:00 every night, and charges the storage battery unit 11 to a charging rate of 90%. Then, at 10:00 in the morning of the next day, the battery is discharged to a charging rate of 40%. At this time, the storage battery management system 1 discharges power from the grid power through the pass-through output from the output unit 27 every night from 23:00 to 10:00 in the morning, and outputs power from the storage battery unit 11 for several hours from 10:00 in the morning. do. Then, the output from the storage battery unit 11 is stopped, and the power from the system power is output again from the output unit 27 by pass-through output.

Next, the operation of setting the timer of the storage battery management system 1 or the charging/discharging capacity of the storage battery unit 11 will be described. FIG. 8 is a flow chart showing the operation of setting the timer or capacity of the storage battery management system in the embodiment.

The first control unit 13 determines whether or not to set the timer (step S10). The first control unit 13 determines whether or not to set a timer for determining the timing at which the power control performed by the second control unit 21 is performed. Here, the timer setting is specifically the setting of the charging start time, the charging end time, the discharge start time, the discharge end time, and the like.

When the first control unit 13 determines to set the timer (Yes in step S10), the information terminal 30 receives input from the user of the charging start time, the charging end time, and the discharging start time and the discharging end time. Accept (step S11).

When the first control unit 13 does not determine to set the timer (No in step S10), the process proceeds to step S12.

Next, the first control unit 13 determines whether or not to input a condition regarding charge/discharge capacity (step S12). Here, the charge/discharge capacity is the capacity of power charged to the storage battery unit 11 or the capacity of power discharged from the storage battery unit 11 . Inputting a condition regarding the charge/discharge capacity means that the information terminal 30 accepts input of information regarding the capacity of the power charged to the storage battery unit 11 or the capacity of the power discharged from the storage battery unit 11. good. Specifically, the user may set any numerical value by himself/herself, and recommended settings (high power operation, eco mode operation) are presented to the user from the information terminal 30 or the server device that realizes the cloud. Alternatively, the information terminal 30 or the server device that implements the cloud may automatically set the setting. Specifically, the power capacity charged to the storage battery unit 11 or the power capacity discharged from the storage battery unit 11 may be a charge stop capacity or a discharge stop capacity.

When the first control unit 13 determines to input the condition regarding the charging/discharging capacity (Yes in step S12), the information terminal 30 receives the input of the charging stop capacity or the discharging stop capacity (step S13). The information terminal 30 transmits the information on the charge stop capacity or the discharge stop capacity whose input has been accepted to the first control section 13 via the first communication section 12 .

When the first control unit 13 does not determine to input the condition regarding the charge/discharge capacity (No in step S12), the storage battery management system 1 ends the operation.

Next, the charge/discharge operation of the storage battery management system 1 will be described. FIG. 9 is a flow chart showing charge/discharge operation of the storage battery management system 1 in the embodiment.

First, the first control unit 13 determines whether or not the storage battery pack 10 is set in the power control device 20 (step S20). Here, the power control device 20 may be, for example, a charger/discharger.

When the first control unit 13 determines that the storage battery pack 10 is set in the power control device 20 (Yes in step S20), the first control unit 13 determines whether the current time is within the charge/discharge start time. (Step S21). The first control unit 13 has a clock function and determines whether or not the current time is within the charge/discharge start time set in the received schedule information.

When the first control unit 13 does not determine that the storage battery pack 10 has been set in the power control device 20 (No in step S20), the process returns to step S20. If the first control unit 13 does not determine that the storage battery pack 10 has been set in the power control device 20 , it determines again whether or not the storage battery pack 10 has been set in the power control device 20 .

Next, the second control unit 21 starts power control (step S22). Here, power control is specifically charging to the storage battery unit 11 or discharging from the storage battery unit 11 . Note that the first control unit 13 may start power control instead of the second control unit 21 .

Subsequently, the second control unit 21 continues power control (step S23). Here, power control is specifically charging to the storage battery unit 11 or discharging from the storage battery unit 11 . Note that the first control unit 13 may continue power control instead of the second control unit 21 .

Next, the first control unit 13 determines whether or not the capacity of the storage battery unit 11 is the end capacity of power control (step S24). Specifically, the first control unit 13 determines whether or not the capacity of the storage battery unit 11 subjected to power control is the power control end capacity set in the schedule information acquired by the first control unit 13. .

When the first control unit 13 determines that the capacity of the storage battery unit 11 is not the end capacity of the power control (No in step S24), the first control unit 13 determines whether it is the end time of the power control for the storage battery unit 11. Determine (step S25). The first control unit 13 has a clock function, and determines whether or not the current time in step S25 is the end time of power control for the storage battery unit 11 . Here, the power control is charging to the storage battery unit 11 and discharging from the storage battery unit 11 .

When the first control unit 13 determines that the capacity of the storage battery unit 11 is the power control end capacity (Yes in step S24), the storage battery management system 1 ends the operation.

When the first control unit 13 determines that it is time to end the power control for the storage battery unit 11 (Yes in step S25), the storage battery management system 1 ends the operation.

When the first control unit 13 does not determine that it is time to end power control for the storage battery unit 11 (No in step S25), the process returns to step S23.

Next, the relationship in the operation of the main components of the storage battery management system 1 will be described. FIG. 10 is a diagram showing the relationship between main components of the storage battery management system 1 according to the embodiment.

As shown in 1-1 and 1-2 of FIG. 10 , the information terminal 30 or the server wirelessly transmits the schedule information or the execution information to the first communication unit 12 of the storage battery pack 10 .

Then, the schedule information or the execution information transmitted in 1-1 and 1-2 in FIG. The power control device is a charger, a discharger, or a charger/discharger, and communication with each of the above, such as schedule information, is represented by 2-1, 2-2, and 2-3 in FIG.

The second control unit 21 of the power control device 20 may communicate with the pass-through charging/discharging mechanism and perform pass-through output during the transmissions of 2-1, 2-2, and 2-3. 1-1, 1-2, and 1-3, and 2-1, 2-2, and 2-3, information on the charge capacity of the storage battery unit 11 or discharge from the storage battery unit 11 Information about capacity may be included.

Also, the execution device for instructions 2-1, 2-2, and 2-3 may be the storage battery pack 10 or the power control device 20 (charger, discharger, or charger/discharger).

Incidentally, as shown in 3-1, 3-2, and 3-3, the charger, the discharger, and the charger/discharger may control the pass-through charging/discharging mechanism to perform pass-through output.

In addition, the server transmits an instruction to the storage battery pack 10 in an emergency to update the schedule information indicating the timing to charge or discharge the storage battery pack 10 included in the charge/discharge information to the storage battery pack 10, and the storage battery pack 10 , updates the schedule information included in the charge/discharge information based on the instruction. For example, the server may stop discharging from the storage battery unit 11 and preferentially charge the storage battery unit 11 in an emergency such as a typhoon or flood damage in a neighboring area. Specifically, the server may update the schedule for discharging from the storage battery unit 11 , set it as the schedule for charging the storage battery unit 11 , and transmit the schedule to the first communication unit 12 of the storage battery pack 10 . Information on typhoons, floods, etc. may be determined by the server referring to external information such as weather forecasts and disaster warning information, or the server administrator may determine emergency situations and register information in the server. good too.

[Effects, etc.]
The storage battery management system 1 of the present disclosure includes a storage battery pack 10 and a power control device 20 to which the storage battery pack 10 is attached and detached, and performs power control that is control of at least one of charging and discharging of the storage battery pack 10 . is a first communication unit 12 that receives schedule information indicating a schedule of power control from an information terminal 30 or a server, a second communication unit 15 that communicates with the power control device 20, and based on the received schedule information, and a first control unit 13 that transmits execution information for executing power control to the power control device 20 using the second communication unit 15 .

Thereby, in the storage battery management system 1 of the present disclosure, the storage battery pack 10 can transmit the schedule information to the power control device 20 . Therefore, the storage battery pack 10 itself can perform power control to the storage battery unit 11 .

Also, for example, in the storage battery management system 1 of the present disclosure, the first control unit 13 transmits a command based on schedule information to the power control device 20 as execution information.

Thereby, the storage battery management system 1 of the present disclosure can perform power control by controlling the storage battery pack 10 . Therefore, the storage battery pack 10 itself can perform power control to the storage battery unit 11 .

Further, for example, in the storage battery management system 1 of the present disclosure, the first control unit 13 transmits schedule information as execution information, the power control device 20 receives the schedule information, and controls power based on the received schedule information. is provided with a second control unit 21 for performing

Thereby, the storage battery management system 1 of the present disclosure can perform power control under the control of the power control device 20 . Therefore, the storage battery pack itself can indirectly control the power to the storage battery unit 11 by transmitting the schedule information to the power control device 20 .

Further, for example, in the storage battery management system 1 of the present disclosure, the first communication unit 12 receives schedule information through wireless communication, and the second communication unit 15 transmits execution information through wired communication.

Thereby, the storage battery management system 1 of the present disclosure can use an appropriate communication method according to the installation location and the connection relationship of the devices.

Also, for example, in the storage battery management system 1 of the present disclosure, the first communication unit 12 receives schedule information from the information terminal 30 .

Thereby, in the storage battery management system 1 of the present disclosure, the storage battery pack 10 can receive the schedule information through communication. Therefore, the storage battery pack itself can directly or indirectly control the power to the storage battery unit 11 by transmitting the schedule information to the power control device.

Also, for example, in the storage battery management system 1 of the present disclosure, the first communication unit 12 receives schedule information from the server.

Thereby, in the storage battery management system 1 of the present disclosure, the storage battery pack 10 can receive the schedule information through communication. Therefore, the storage battery pack itself can directly or indirectly control the power to the storage battery unit 11 by transmitting the schedule information to the power control device.

Further, for example, in the storage battery management system 1 of the present disclosure, the information terminal 30 and the server each determine charge/discharge information for at least one storage battery pack 10 among the plurality of storage battery packs 10 .

Thereby, the storage battery management system 1 of the present disclosure can control the plurality of storage battery packs 10 .

Further, for example, in the storage battery management system 1 of the present disclosure, the server instructs the storage battery pack 10 in an emergency to update the schedule information indicating the timing to charge or discharge the storage battery pack 10 included in the charge/discharge information. The information is transmitted to the storage battery pack 10, and the storage battery pack 10 updates the schedule information included in the charge/discharge information based on the instruction.

Thereby, the storage battery management system 1 of the present disclosure can perform charging and discharging at appropriate timing in an emergency.

Further, for example, in the storage battery management system 1 of the present disclosure, the information terminal 30 is a mobile terminal.

Thereby, the storage battery management system 1 of the present disclosure can set schedule information and the like using a mobile terminal such as a smart phone.

Also, for example, in the storage battery management system 1 of the present disclosure, the server is a dedicated terminal.

Thereby, the storage battery management system 1 of the present disclosure can set schedule information and the like using a dedicated terminal such as a server.

Further, for example, in the storage battery management system 1 of the present disclosure, the power control device 20 performs both charging and discharging of the storage battery pack 10 as power control.

Thereby, the storage battery management system 1 of the present disclosure can charge and discharge the storage battery section 11 of the storage battery pack 10 .

Further, for example, in the storage battery management system 1 of the present disclosure, the power control device 20 includes an input unit 26 to which the first power for charging the storage battery pack 10 is input, and a first power obtained by discharging the storage battery pack 10. An output unit 27 for outputting two powers, and a first switching unit 22 for switching between outputting the first power input to the input unit 26 as it is and outputting the second power to the output unit 27 .

Thereby, the storage battery management system 1 of the present disclosure can output electric power from the output unit 27 while charging the storage battery unit 11 of the storage battery pack 10 .

(others)
Although the embodiments have been described above, the present disclosure is not limited to the above embodiments.

For example, in the above embodiments, a process executed by a specific processing unit may be executed by another processing unit. In addition, the order of multiple processes may be changed, and multiple processes may be executed in parallel.

Also, in the above embodiments, each component may be realized by executing a software program suitable for each component. Each component may be realized by reading and executing a software program recorded in a recording medium such as a hard disk or a semiconductor memory by a program execution unit such as a CPU or processor.

Also, each component may be realized by hardware. For example, each component may be a circuit (or integrated circuit). These circuits may form one circuit as a whole, or may be separate circuits. These circuits may be general-purpose circuits or dedicated circuits.

Also, general or specific aspects of the present disclosure may be embodied in a system, apparatus, method, integrated circuit, computer program or recording medium such as a computer-readable CD-ROM. Also, general or specific aspects of the present disclosure may be implemented in any combination of systems, devices, methods, integrated circuits, computer programs and recording media.

For example, the present disclosure may be implemented as a program for causing a computer to execute the lighting control method of the above embodiments. The present disclosure may be implemented as a computer-readable non-transitory recording medium in which such programs are recorded.

In addition, forms obtained by applying various modifications to each embodiment that a person skilled in the art can think of, or realized by arbitrarily combining the components and functions of each embodiment within the scope of the present disclosure. Also included in the present disclosure is the form of

10 storage battery pack 12 first communication unit 13 first control unit 15 second communication unit 20 power control device 21 second control unit 22 first switching unit 26 input unit 27 output unit 30 information terminal

Claims (13)

a battery pack;
A power control device to which the storage battery pack is attached and detached and performs power control that is at least one control of charging and discharging of the storage battery pack,
The storage battery pack is
a first communication unit that receives schedule information indicating the power control schedule from an information terminal or a server;
a second communication unit that communicates with the power control device;
A storage battery management system comprising: a first control unit that transmits execution information for executing the power control to the power control device using the second communication unit based on the received schedule information. The storage battery management system according to claim 1, wherein the first control unit transmits a command based on the schedule information to the power control device as the execution information. The first control unit transmits the schedule information as the execution information,
The power control device is
The storage battery management system according to claim 1, comprising a second control unit that receives the schedule information and performs the power control based on the received schedule information. The first communication unit receives the schedule information by wireless communication,
The storage battery management system according to any one of claims 1 to 3, wherein the second communication unit transmits the execution information through wired communication. The storage battery management system according to any one of claims 1 to 4, wherein the first communication unit receives schedule information from the information terminal. The storage battery management system according to any one of claims 1 to 4, wherein the first communication unit receives schedule information from the server. The information terminal and the server each determine charge/discharge information for at least one of the plurality of battery packs,
The storage battery management system according to any one of claims 1 to 4. The server transmits an instruction to the storage battery pack in an emergency to update schedule information indicating a timing to charge or discharge the storage battery pack included in the charge/discharge information to the storage battery pack in an emergency,
the storage battery pack updates the schedule information included in the charge/discharge information based on the instruction;
The storage battery management system according to claim 7. The information terminal is a mobile terminal,
The storage battery management system according to any one of claims 1 to 8. The server is a dedicated terminal,
The storage battery management system according to any one of claims 1 to 9. The first control unit transmits a command based on charge capacity information as the execution information to the power control device.
The storage battery management system according to any one of claims 1 to 10. The power control device performs both charging and discharging of the storage battery pack as the power control.
The storage battery management system according to any one of claims 1 to 11. The power control device is
an input unit into which first electric power for charging the storage battery pack is input;
an output unit that outputs second power obtained by discharging the storage battery pack;
The storage battery management system according to claim 12, wherein the output unit includes a switching unit that switches between outputting the first power input to the input unit as it is and outputting the second power.

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